Circles

Given that OP = 8 cm

And AB = 12 cm

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

∴ AP = PB = 6 cm

In the right angled ΔOAP using Pythagoras theorem,

⇒ OA² = OP² + AP²

⇒ OA² = 8² + 6²

⇒ OA² = 64 + 36

⇒ OA² = 100

⇒ OA = 10cm

So, the diameter of the circle is (2×10) = 20cm (Diameter = 2×Radius).

Given that diameter = 26cm

Radius = Diameter / 2 = 26 /2 = 13cm

So, OA = 13cm

And AB = 24 cm

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

∴ AP = PB = 12 cm

In the right angled ΔOAP using Pythagoras theorem,

⇒ OA² = OP² + AP²

⇒ 13² = OP² + 12²

⇒ 169 = OP² + 144

⇒ OP² = 25

⇒ OP = 5cm

So, the distance of chord from the center is 5cm.

Given that

Radius = 34cm

So, OA = 34cm

And OP = 30 cm

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

∴ AP = PB,

AB = 2PB

In the right angled ΔOAP using Pythagoras theorem,

⇒ OA² = OP² + AP²

⇒ 34² = 30² + AP²

⇒ 1156 = 900 + AP²

⇒ AP² = 256

⇒ AP = 16cm

So, the length of chord is 16× 2 = 32cm (AB = 2AP)

Given that

Radius = 41 units

So, OP = 41 units

And PQ = 80 units

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

∴ PM = MQ = 40 cm

In the right angled ΔOAP using Pythagoras theorem,

⇒ OP² = OM² + PM²

⇒ 41² = OM² + 40²

⇒ 1681 = OM² + 1600

⇒ OM² = 81

⇒ OM = 9 units

So, the distance of chord from the center is 9 units.

We draw a perpendicular on chord AB from O.

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

Therefore,

AM = MB …….(1)

OM is also perpendicular to chord PQ of smaller circle.

Therefore,

PM = MQ ………….(2)

Subtracting (2) from (1)

AM-PM = MB-MQ

⇒ AP = BQ

Hence Proved.

We draw a circle with center O and AB, CD are the chords of this circle. Diameter PQ bisects AB and CD at M and N respectively.

We know that the line from the center bisecting the chord is perpendicular to the chord.

Therefore,

∠ OMA = ∠ OMB = 90°

Also, ∠ ONC = ∠ OND = 90°

∠ OMA + ∠ ONC = 90° + 90° = 180°

Hence the two chords, AB and CD are parallel to each other.

Given radius of circle is 10cm

OA = OD = 10cm

AB = CD = 16cm

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

CQ = QD = 8cm

In right angled ΔOQD using the Pythagoras theorem

OD² = OQ² + QD²

10² = OQ² + 8²

100 = OQ² + 64

OQ² = 36

OQ = 6cm

Therefore the chord CD is at 6cm from the center.

We know that Congruent chords of a circle are equidistant from the center of the circle.

As AB and CD are equal in length, they are equidistant.

∴ OP = OQ = 6cm

Given radius of circle is 13cm

OA = OD = 13cm

OQ = OP = 16cm

We know that a perpendicular drawn from the centre of a circle on its chord bisects

the chord.

CQ = QD

CD = 2×QD

In right angled ΔOQD using the Pythagoras theorem

OD² = OQ² + QD²

13² = 5² + QD²

169 = 25 + QD²

QD² = 144

QD = 12cm

Therefore the length of chord CD = 2×12 = 24cm

We know that The chords of a circle equidistant from the center of a circle are congruent

As AB and CD are equidistant, they are equal in length.

∴ AB = CD = 24cm

Given that PM = PN

We know that Congruent chords of a circle are equidistant from the center of the circle.

Therefore, AC = CB ………………(1)

Also,

A perpendicular drawn from the centre of a circle on its chord bisects

the chord.

CB bisects PN as PB = BN,

Similarly, CA bisects PM as PA = AM.

In ΔAPC and ΔBPC,

∠CAP = ∠ CBP = 90°

PC = PC (common side)

AC = CB (From eq (1))

∴ ΔAPC≅ ΔBPC (RHS congruence)

∴ ∠ APC = ∠ BPC (by CPCT)

Hence proved that PC is the bisector of ∠ NPM.

Steps of Construction:

1.Construct ΔABC of given dimensions.

2.Draw bisectors of two angles, ∠A and ∠B.

3.Denote the point of intersection as O.

4.Draw perpendicular OP on AB.

5.Draw a circle with O as center and OP as radius.

Steps of Construction:

1.Construct ΔPQR of given dimensions.

2.Draw perpendicular bisectors of two sides, QR and PR.

3.Denote the point of intersection as O.

4.Draw a circle with O as center and OP as radius.

Steps of Construction:

1.Construct ΔXYZ of given dimensions.

2.Draw bisectors of two angles, ∠X and ∠Y.

3.Denote the point of intersection as O.

4.Draw perpendicular OA on XY.

5.Draw a circle with O as center and OA as radius.

Steps of Construction:

1.Construct ΔLMN of given dimensions.

2.Draw perpendicular bisectors of two sides, LM and MN.

3.Denote the point of intersection as O.

4.Draw a circle with O as center and OM as radius.

Steps of Construction:

1.Construct ΔDEF of given dimensions.

2.Draw perpendicular bisectors of two sides, DE and EF.

3.Denote the point of intersection as O.

4.Draw a circle with O as center and OD as radius.

Given that

Radius = 10cm

So, OA = 10cm

And OP = 6 cm

We know that a perpendicular drawn from the centre of a circle on its chord bisects

the chord.

∴ AP = PB,

AB = 2PB

In the right angled ΔOAP using Pythagoras theorem,

⇒ OA² = OP² + AP²

⇒ 10² = 6² + AP²

⇒ 100 = 36 + AP²

⇒ AP² = 64

⇒ AP = 8cm

So, the length of chord is 8× 2 = 16cm (AB = 2AP)

The correct answer is A.

Incenter is defined as the point of occurrence of all angle bisectors of a triangle. Incircle is the corresponding circle formed with incenter as the center.

Circle passing through all the vertices of a triangle is called circumcircle of the triangle and the center of the circle is called the circumcenter of the triangle.

Given that OP = 5 cm

And AB = 24cm

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

∴ AP = PB = 12 cm

In the right angled ΔOAP using Pythagoras theorem,

⇒ OA² = OP² + AP²

⇒ OA² = 5² + 12²

⇒ OA² = 25 + 144

⇒ OA² = 169

⇒ OA = 13cm

Hence, The correct option is B.

The longest chord of a circle is its diameter.

The length of diameter is 2× radius = 2×2.9 = 5.8cm

Hence, The correct answer is D.

The longest distance of a point, from the center, within the circle is its radius = 4cm.

For distance = 4cm , it is on the circle.

For distance>4.2cm, it is outside the circle.

Hence, The correct answer is C.

Let, length of AB = 6cm and length of CD = 8cm

Radius of circle = 5cm

OB = OC = 5cm

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

AM = MB = 3cm

Also, CN = ND = 4cm

In ΔOMB,

⇒ OB² = OM² + MB²

⇒ 5² = OM² + 3²

⇒ OM² = 25-9

⇒ OM² = 16

⇒ OM = 4cm

In ΔONC,

⇒ OC² = ON² + CN²

⇒ 5² = ON² + 4²

⇒ ON² = 25-16

⇒ ON² = 9

⇒ ON = 3cm

Distance between AB and CD = OM + ON = 4 + 3 = 7cm

Hence the correct option is D.

Steps of Construction:

1.Construct ΔDSP of given dimensions.

2.Draw perpendicular bisectors of two sides, DS and SP.

3.Denote the point of intersection as O.

4.Draw a circle with O as center and OD as radius.

As we know that for an equilateral triangle, the incenter is same as the circumcenter.

5.Taking O as center, and the OM as the radius draw a circle.

Circumradius = OP = 4.3cm

Inradius = OM = 2.1cm

For an equilateral triangle, Circumradius = 2×Inradius.

Steps of Construction:

1. Construct ΔNTS of given dimensions.

2.Draw bisectors on ∠T and ∠S.

3.The point of intersection as B.

4.Draw perpendicular on NT from B.

5. With B as center and length of perpendicular as radius, draw a circle.

6.Draw perpendicular bisectors of ST and TN.

7.The point of intersection is A.

8. With A as center, and AS as radius draw a circle.

We join C to S to form ΔCPS.

CP = 5 (given)

Radius of circle = CT = 13 (given)

Therefore CS = 13 (radius of the same circle)

In ΔCPS,

⇒ CS² = CP² + PS²

⇒ 13² = 5² + PS²

⇒ PS² = 169-25

⇒ PS² = 144

⇒ PS = 12 units

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

PS = RP = 12 units

RS = 2×PS = 2×12 = 24 units

In the figure, we join PA and PD. Draw perpendiculars on AB and CD from P as PM and PN respectively.

∠AEP = ∠ DEP (given)

So, ∠PEN = ∠PEM (M and N are points on line AE and ED respectively)

In ΔPEN and ΔPEM,

∠PNE = ∠PME = 90°

∠PEN = ∠PEM

PE = PE (common)

Therefore, Δ PEN ≅ ΔPEM (by AAS congruence)

∴ PN = PM (by CPCT)

We know that The chords of a circle equidistant from the center of a circle are congruent.

So, AB = CD.

Hence proved.

We know that a perpendicular drawn from the center of a circle on its chord bisects

the chord.

So, AE = EB

In ΔACE and ΔBCE,

AE = EB

∠AEC = ∠BEC = 90°

CE = CE (common)

Δ ACE ≅ Δ BCE (By SAS congruence)

Therefore, AC = BC (by CPCT)

Hence proved that ABC is an isosceles triangle.